Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Reduced cellular glucose uptake in response to insulin and decreased expression of a mitochondrial ETC complex subunit in <i>ALAS1</i>-knockdown C2C12 myocytes. by Shinichi Saitoh (4794345)

Geometric mean anti-<i>Na</i>-GST-1 IgG subclass levels over time. by David J. Diemert (8135568)

Growth Kinetics of Elementary Spiral Steps on Ice Prism Faces Grown in Vapor and Their Temperature Dependence by Genki Miyamoto (13914416)

Subjects:

Step length asymmetry and step width during split-belt adaptation. by Samantha Jeffcoat (22783930)

[2+2] Cycloadditions with an Iron Carbene: A Critical Step in Enyne Metathesis by Melissa R. Hoffbauer (5452868)

Mean survival proportions (to 28 d) for each incision metric score as rated by examiners at 7 d for all treatments combined. by April S. Cameron (8622711)

Deficiency of CRL4^CRBN promotes the destruction of BK channel α subunit. by Tianyu Song (4797417)

Metformin inhibits glutaminase activity in a dose dependent manner: from 17.5% at 10 mM up to 68% at 100 mM (A) (* p<0.05). by M. Mar Díaz-Herrero (646639)

Growth kinetics of the spheroids in the microfluidic device. by Sreerupa Sarkar (9628788)

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Decrease in preferred walking speed with distance walked for subjects with amputation. by Nidhi Seethapathi (3258591)

Transient kinetic analysis of the S100A4-N-ERMAD interaction. by Beáta Biri-Kovács (4020650)

“…<p>(A, B) 2 μM N-ERMAD or F2 lobe (respectively) was mixed with an equal volume of S100A4 in different concentrations and a decrease in intrinsic Trp fluorescence was monitored over time (left panel). …”

The image illustrates the five steps of the experiment. by Deborah Ribeiro Frazão (9188152)

(a) a top view of step1 of fabrication flow, (b) cross view of Fig 2(a) along cutline A, (c) cross view of Fig 2(a) along cutline B, (d) top view of step 2 of fabrication flow, (e)... by Xiaoshi Jin (15675049)